Your search keyword '"V. Rykalin"' showing total 8 results

1. A comparison of proton stopping power measured with proton CT and x-ray CT in fresh postmortem porcine structures

Author

James S. Welsh, Mark Pankuch, Caesar E. Ordoñez, Alec M. Block, Don F. DeJongh, George Coutrakon, John R. Winans, Ethan A. DeJongh, Nicholas T. Karonis, Andrew W. Best, Kirk L. Duffin, V. Rykalin, Greg DeFillippo, Christina Sarosiek, Reinhard W. Schulte, and Courtney L. Hentz

Subjects

Scanner, Materials science, Proton, Swine, FOS: Physical sciences, Stopping power, Article, Hounsfield scale, Proton Therapy, Animals, Humans, Radiation treatment planning, Proton therapy, Range (particle radiation), business.industry, Phantoms, Imaging, Radiotherapy Planning, Computer-Assisted, X-Rays, X-ray, General Medicine, Physics - Medical Physics, Radiography, Medical Physics (physics.med-ph), Protons, Nuclear medicine, business, Tomography, X-Ray Computed

Abstract

Purpose: Currently, calculations of proton range in proton therapy patients are based on a conversion of CT Hounsfield Units of patient tissues into proton relative stopping power. Uncertainties in this conversion necessitate larger proximal and distal planned target volume margins. Proton CT can potentially reduce these uncertainties by directly measuring proton stopping power. We aim to demonstrate proton CT imaging with complex porcine samples, to analyze in detail three-dimensional regions of interest, and to compare proton stopping powers directly measured by proton CT to those determined from x-ray CT scans. Methods: We have used a prototype proton imaging system with single proton tracking to acquire proton radiography and proton CT images of a sample of porcine pectoral girdle and ribs, and a pig's head. We also acquired close in time x-ray CT scans of the same samples, and compared proton stopping power measurements from the two modalities. In the case of the pig's head, we obtained x-ray CT scans from two different scanners, and compared results from high-dose and low-dose settings. Results: Comparing our reconstructed proton CT images with images derived from x-ray CT scans, we find agreement within 1% to 2% for soft tissues, and discrepancies of up to 6% for compact bone. We also observed large discrepancies, up to 40%, for cavitated regions with mixed content of air, soft tissue, and bone, such as sinus cavities or tympanic bullae. Conclusions: Our images and findings from a clinically realistic proton CT scanner demonstrate the potential for proton CT to be used for low-dose treatment planning with reduced margins., Accepted for publication in Medical Physics

Published

2021

2. Analysis of characteristics of images acquired with a prototype clinical proton radiography system

Author

Caesar E. Ordoñez, Christina Sarosiek, Ethan A. DeJongh, Nicholas T. Karonis, George Coutrakon, John R. Winans, V. Rykalin, Kirk L. Duffin, Mark Pankuch, Don F. DeJongh, and James S. Welsh

Subjects

Computer science, Image quality, Radiography, FOS: Physical sciences, Imaging phantom, Article, 030218 nuclear medicine & medical imaging, 03 medical and health sciences, 0302 clinical medicine, Optical transfer function, Image noise, Image Processing, Computer-Assisted, Humans, Computer vision, Line pair, Child, Image resolution, Pixel, business.industry, Phantoms, Imaging, Water, General Medicine, Physics - Medical Physics, 3. Good health, 030220 oncology & carcinogenesis, Medical Physics (physics.med-ph), Artificial intelligence, Protons, business, Head

Abstract

Verification of patient specific proton stopping powers obtained in the patient treatment position can be used to reduce the distal margins needed in particle beam planning. Proton radiography can be used as a pre-treatment instrument to verify integrated stopping power consistency with the treatment planning CT. Although a proton radiograph is a pixel by pixel representation of integrated stopping powers, the image may also be of high enough quality and contrast to be used for patient alignment. This investigation qualifies the accuracy and image quality of a prototype proton radiography system on a clinical proton delivery system. We have developed a clinical prototype proton radiography system designed for integration into efficient clinical workflows. We tested the images obtained by this system for water-equivalent thickness (WET) accuracy, image noise, and spatial resolution. We evaluated the WET accuracy by comparing the average WET and rms error in several regions of interest (ROI) on a proton radiograph of a custom peg phantom. We measured the spatial resolution on a CATPHAN Line Pair phantom and a custom edge phantom by measuring the 10% value of the modulation transfer function (MTF). In addition, we tested the ability to detect proton range errors due to anatomical changes in a patient with a customized CIRS pediatric head phantom and inserts of varying WET placed in the posterior fossae of the brain. We took proton radiographs of the phantom with each insert in place and created difference maps between the resulting images. Integrated proton range was measured from an ROI in the difference maps., 11 pages, 7 figures, Submitted to Medical Physics

Published

2021

3. Water-equivalent path length calibration of a prototype proton CT scanner

Author

Baldev Patyal, Reinhard W. Schulte, Hartmut Sadrozinski, Vladimir Bashkirov, Andrew J. Wroe, V. Rykalin, A Ghebremedhin, George Coutrakon, R. F. Hurley, and P Koss

Subjects

Scanner, Materials science, Proton, business.industry, Calibration curve, Detector, General Medicine, Imaging phantom, Calorimeter, Optics, Path length, Calibration, business, Nuclear medicine

Abstract

Purpose: The authors present a calibration method for a prototype protoncomputed tomography (pCT) scanner. The accuracy of these measurements depends upon careful calibration of the energy detector used to measure the residual energy of the protons that passed through the object. Methods: A prototype pCT scanner with a cesium iodide (CsI(Tl)) crystal calorimeter was calibrated by measuring the calorimeter response for protons of 200 and 100 MeV initial energies undergoing degradation in polystyrene plates of known thickness and relative stopping power (RSP) with respect to water. Calibration curves for the two proton energies were obtained by fitting a second-degree polynomial to the water-equivalent path length versus calorimeter response data. Using the 100 MeV calibration curve, the RSP values for a variety of tissue-equivalent materials were measured and compared to values obtained from a standard depth-dose range shift measurement using a water-tank. A cylindrical water phantom was scanned with 200 MeV protons and its RSP distribution was reconstructed using the 200 MeV calibration. Results: It is shown that this calibration method produces measured RSP values of various tissue-equivalent materials that agree to within 0.5% of values obtained using an established water-tank method. The mean RSP value of the water phantom reconstruction was found to be 0.995 ± 0.006. Conclusions: The method presented provides a simple and reliable procedure for calibration of a pCT scanner.

Published

2012

4. SU-E-T-350: Calibration of a Prototype Proton CT Scanner

Author

Reinhard W. Schulte, V. Rykalin, H Sadrozinsk, Vladimir Bashkirov, Andrew J. Wroe, F. Hurley, A Ghebremedhin, Baldev Patyal, and Scott Penfold

Subjects

Physics, Scanner, Accuracy and precision, Tomographic reconstruction, Proton, Physics::Instrumentation and Detectors, business.industry, Calibration curve, General Medicine, Calorimeter, Optics, Path length, Calibration, business

Abstract

Purpose: To calibrate a novel protonCT scanner using polystyrene degraders of accurately known thickness and relative stopping power.Methods: A prototype protonCT scanner was constructed and installed on a horizontal proton research beam line for further study of this novel, potentially low‐dose tomographic imaging modality. The protonCT scanner registers individual protons up to a maximum rate of about 105 protons/sec, recording their entry and exit coordinates and directions with high‐resolution silicon strip detectors, as well as their residual energy by stopping them in an augmented 18‐crystal CsI calorimeter. To avoid uncertainties in the mean excitation energy (I) of water when converting energy loss to water equivalent path length (WEPL) via the Bethe‐Bloch equation, the response of the calorimeter was calibrated using polystyrene plates of known water‐equivalent thickness (WET). Stacks of polystyrene plates of variable thickness were placed between the protonCTdetectors and about 3 × 105 protons were recorded for each thickness. For each proton event, the calorimeter response was derived from the weighted sum of the response of the 18 crystals, taking into account variations in the sensitivity of each crystal. A Gaussian distribution function was fitted to the response data at each WET, and the mean of each distribution was used to establish the WEPL calibration curve. Results: For protons of 100 MeV and 200 MeV, the mean response of the calorimeter was obtained for 7–8 different WET values (including zero) and the WEPL vs. response calibration curve was fitted with a quadratic polynomial with an excellent goodness of fit. A WEPL measurement accuracy of 1 mm or better can be achieved by measuring the calorimeter response of about 150 protons Conclusions: This work is an important step towards a thorough investigation of protoncomputed tomography for therapeutic and imaging applications. Funded in part by DOD Contract W81XWH‐08‐1‐0205 and the Department of Radiation Medicine, Loma Linda University Medical Center

Published

2011

5. A comparison of proton stopping power measured with proton CT and x-ray CT in fresh postmortem porcine structures.

Author

DeJongh DF, DeJongh EA, Rykalin V, DeFillippo G, Pankuch M, Best AW, Coutrakon G, Duffin KL, Karonis NT, Ordoñez CE, Sarosiek C, Schulte RW, Winans JR, Block AM, Hentz CL, and Welsh JS

Subjects

Animals, Humans, Phantoms, Imaging, Protons, Radiography, Radiotherapy Planning, Computer-Assisted, Swine, Tomography, X-Ray Computed, X-Rays, Proton Therapy

Abstract

Purpose: Currently, calculations of proton range in proton therapy patients are based on a conversion of CT Hounsfield units of patient tissues into proton relative stopping power. Uncertainties in this conversion necessitate larger proximal and distal planned target volume margins. Proton CT can potentially reduce these uncertainties by directly measuring proton stopping power. We aim to demonstrate proton CT imaging with complex porcine samples, to analyze in detail three-dimensional regions of interest, and to compare proton stopping powers directly measured by proton CT to those determined from x-ray CT scans., Methods: We have used a prototype proton imaging system with single proton tracking to acquire proton radiography and proton CT images of a sample of porcine pectoral girdle and ribs, and a pig's head. We also acquired close in time x-ray CT scans of the same samples and compared proton stopping power measurements from the two modalities. In the case of the pig's head, we obtained x-ray CT scans from two different scanners and compared results from high-dose and low-dose settings., Results: Comparing our reconstructed proton CT images with images derived from x-ray CT scans, we find agreement within 1% to 2% for soft tissues and discrepancies of up to 6% for compact bone. We also observed large discrepancies, up to 40%, for cavitated regions with mixed content of air, soft tissue, and bone, such as sinus cavities or tympanic bullae., Conclusions: Our images and findings from a clinically realistic proton CT scanner demonstrate the potential for proton CT to be used for low-dose treatment planning with reduced margins., (© 2021 American Association of Physicists in Medicine.)

Published

2021

6. Analysis of characteristics of images acquired with a prototype clinical proton radiography system.

Author

Sarosiek C, DeJongh EA, Coutrakon G, DeJongh DF, Duffin KL, Karonis NT, Ordoñez CE, Pankuch M, Rykalin V, Winans JR, and Welsh JS

Subjects

Child, Humans, Image Processing, Computer-Assisted, Phantoms, Imaging, Radiography, Water, Head, Protons

Abstract

Purpose: Verification of patient-specific proton stopping powers obtained in the patient's treatment position can be used to reduce the distal and proximal margins needed in particle beam planning. Proton radiography can be used as a pretreatment instrument to verify integrated stopping power consistency with the treatment planning CT. Although a proton radiograph is a pixel by pixel representation of integrated stopping powers, the image may also be of high enough quality and contrast to be used for patient alignment. This investigation quantifies the accuracy and image quality of a prototype proton radiography system on a clinical proton delivery system., Methods: We have developed a clinical prototype proton radiography system designed for integration into efficient clinical workflows. We tested the images obtained by this system for water-equivalent thickness (WET) accuracy, image noise, and spatial resolution. We evaluated the WET accuracy by comparing the average WET and rms error in several regions of interest (ROI) on a proton radiograph of a custom peg phantom. We measured the spatial resolution on a CATPHAN Line Pair phantom and a custom edge phantom by measuring the 10% value of the modulation transfer function (MTF). In addition, we tested the ability to detect proton range errors due to anatomical changes in a patient with a customized CIRS pediatric head phantom and inserts of varying WET placed in the posterior fossae of the brain. We took proton radiographs of the phantom with each insert in place and created difference maps between the resulting images. Integrated proton range was measured from an ROI in the difference maps., Results: We measured the WET accuracy of the proton radiographic images to be ±0.2 mm (0.33%) from known values. The spatial resolution of the images was 0.6 lp/mm on the line pair phantom and 1.13 lp/mm on the edge phantom. We were able to detect anatomical changes producing changes in WET as low as 0.6 mm., Conclusion: The proton radiography system produces images with image quality sufficient for pretreatment range consistency verification., (© 2021 American Association of Physicists in Medicine.)

Published

2021

7. Technical Note: A fast and monolithic prototype clinical proton radiography system optimized for pencil beam scanning.

Author

DeJongh EA, DeJongh DF, Polnyi I, Rykalin V, Sarosiek C, Coutrakon G, Duffin KL, Karonis NT, Ordoñez CE, Pankuch M, Winans JR, and Welsh JS

Subjects

Calibration, Humans, Radiography, Water, Proton Therapy, Protons

Abstract

Purpose: To demonstrate a proton-imaging system based on well-established fast scintillator technology to achieve high performance with low cost and complexity, with the potential of a straightforward translation into clinical use., Methods: The system tracks individual protons through one (X, Y) scintillating fiber tracker plane upstream and downstream of the object and into a 13-cm -thick scintillating block residual energy detector. The fibers in the tracker planes are multiplexed into silicon photomultipliers (SiPMs) to reduce the number of electronics channels. The light signal from the residual energy detector is collected by 16 photomultiplier tubes (PMTs). Only four signals from the PMTs are output from each event, which allows for fast signal readout. A robust calibration method of the PMT signal to residual energy has been developed to obtain accurate proton images. The development of patient-specific scan patterns using multiple input energies allows for an image to be produced with minimal excess dose delivered to the patient., Results: The calibration of signals in the energy detector produces accurate residual range measurements limited by intrinsic range straggling. We measured the water-equivalent thickness (WET) of a block of solid water (physical thickness of 6.10 mm) with a proton radiograph. The mean WET from all pixels in the block was 6.13 cm (SD 0.02 cm). The use of patient-specific scan patterns using multiple input energies enables imaging with a compact range detector., Conclusions: We have developed a prototype clinical proton radiography system for pretreatment imaging in proton radiation therapy. We have optimized the system for use with pencil beam scanning systems and have achieved a reduction of size and complexity compared to previous designs., (© 2020 American Association of Physicists in Medicine.)

Published

2021

8. Water-equivalent path length calibration of a prototype proton CT scanner.

Author

Hurley RF, Schulte RW, Bashkirov VA, Wroe AJ, Ghebremedhin A, Sadrozinski HF, Rykalin V, Coutrakon G, Koss P, and Patyal B

Subjects

Calibration, Image Processing, Computer-Assisted, Uncertainty, Phantoms, Imaging, Protons, Tomography, X-Ray Computed instrumentation, Water

Abstract

Purpose: The authors present a calibration method for a prototype proton computed tomography (pCT) scanner. The accuracy of these measurements depends upon careful calibration of the energy detector used to measure the residual energy of the protons that passed through the object., Methods: A prototype pCT scanner with a cesium iodide (CsI(Tl)) crystal calorimeter was calibrated by measuring the calorimeter response for protons of 200 and 100 MeV initial energies undergoing degradation in polystyrene plates of known thickness and relative stopping power (RSP) with respect to water. Calibration curves for the two proton energies were obtained by fitting a second-degree polynomial to the water-equivalent path length versus calorimeter response data. Using the 100 MeV calibration curve, the RSP values for a variety of tissue-equivalent materials were measured and compared to values obtained from a standard depth-dose range shift measurement using a water-tank. A cylindrical water phantom was scanned with 200 MeV protons and its RSP distribution was reconstructed using the 200 MeV calibration., Results: It is shown that this calibration method produces measured RSP values of various tissue-equivalent materials that agree to within 0.5% of values obtained using an established water-tank method. The mean RSP value of the water phantom reconstruction was found to be 0.995 ± 0.006., Conclusions: The method presented provides a simple and reliable procedure for calibration of a pCT scanner.

Published

2012